Excitation of transducers and square wave generators employed therefor



lMarch 17, 1970 E F. GRossoEHME 3,501,687

EXCITATION OF TRANSDUCERS AND SQUARE WAVE GENERATORS EMPLOYED THEREFOR Filed Nov. 9, 1965 3,501,687 EXCITATION F TRANSDUCERS AND SQUARE WAVE GENERATORS EMPLOYED THEREFOR Floyd Grossoehme, Cincinnati, Ohio, assignor to General Electric Company, a corporation of New York Filed Nov. 9, 1965, Ser. No. 506,993 Int. Cl. H02m 5/10 U.S. 'CL 323-51 2 lClaims ABSTRACT 0F THE DISCLOSURE The disclosure shows improved means for exciting. a position transducer from a voltage. source which var les both in frequency and amplitude. Positive and negative reference voltages of equal magnitude are generated from the power source. These reference voltages are respectlvely applied to the collectors of a pair of transistors which are respectively applied to the collectors of a-pa1r of transistors which are interconnected at their emitters. The common emitter connection is connected to the primary of a transformer. A square wave is generated from the power source and applied to the bases of the two transmitters, thereby generating a square wave input of fixed amplitude having a frequency corresponding to that of the voltage source. This square wave is then applied to the input winding of a transducer. The output windings of the transducer are connected to a demodulator which is appropriately switched by square wave inputs from the transformer thereto to provide an output signal reflecting the degree of displacement of the coupling core of the transducer from a desired position. A D-C signal is also derived from the power source to indicate the actual frequency. The desired and actual signals are summed to provide an error signal.

The present invention relates to improvements in the excitation of transducers and to improvements in the generation of square wave voltages for this and other purposes.

The present invention is best understood by reference to the motivating environment therefor. In controlling the rate of operation of a prime mover such as a gas turbine engine, it is an accepted practice to generate direct current signals indicative of an actual rate of operation and a desired rate of operation. These signals are summed algebraically to derive an error signal which is then employed to change the rate of operation of the prime mover and bring it to what is the desired rate.

It is a known practice in the generation of the demand speed signal to employ a transducer of the typel comprising a primary winding and a pair of opposed secondary windings. The magnetic coupling between the primary and secondary windings is controlled by a displaceable core which may be. connected to a throttle or the like under the control of an operator. The amount of coupling between the primary and secondary windings establishes the strength and phase relationship of the output of the secondary windings, and this in turn reflects the desired rate of operation of the prime mover as set by the operator. The accuracy of the output signal from this transducer is a function of the manner in which the primary winding is excited and, accordingly, one object of the invention is to provide improved, simple, and economical means for accurately exciting transducers, of the present type, used in speed control as well as other purposes.

In accomplishing these ends, a square wave voltage having fixed amplitude and preferably equal positive and negative magnitude is employed through the use of improved square wave generating means provided in accordance with another object of the invention.

, United States Patent O ICC The improved electrical circuit provided by the present invention comprises a voltage source, as an alternator, which may be driven by a prime mover and is therefore variable as to frequency and potential. Electrical energy for exciting a transducer having input and output windings is to be derived from this voltage source. The transducer comprises means for varying the coupling between its primary and secondary windings as a function of physical displacement of a control member, whereby the strength of the signal on the output windings is likewise a function of such displacement. Excitation of the transducer is provided by means, connected to the voltage source, which generate a square wave having a fixed voltage amplitude. By impressing this fixed amplitude square wave on the primary winding of the transducer the output on the secondary thereof accurately reflects displacement of the. control member.

The means for generating the square wave voltage impressed upon the transducer preferably comprise a power supply also excited from the voltage source driven by the prime mover and having positive and negative outputs of constant value and preferably of equal magnitude.

A transformer is provided with primary and secondary windings. Means driven from the voltage source provide an actuating voltage which is employed to actuate electronic switching devices for alternately impressing the positive and negative outputs of the power supply aero-ss the primary winding of the transformer. A relatively large capacitance is provided in the switching means impressing the positive and negative voltages across the primary of the transformer to obtain an accurate square wave voltage output in the secondary thereof, irrespective of any asymmetrical hysteresis conditions in the transformer. The square wave voltage so generated in the secondary of the transformer is then impressed on the primary winding of the transducer.

-Further secondaries of the transformer may be employed to derive the D-C voltage which would be indicative to the actual speed of the prime mover and in a phase responsive demodulating means to which the output of the transducer is also connected and which also provides the D-C signal indicative of a desired speed.

The above and other related objects and features of the invention will be apparent from a reading of the following description of the disclosure found in the accompanying drawing and the novelty thereof pointed out in the appended claims.

The single figure in the drawing is a schematic representation of an electrical circuit embodying the present invention.

In the circuit shown in the drawing, an alternator 10 is mechanically driven from a prime mover 1x2". While the illustrated circuit is a fragmentary portion of a control circuit for many different operating parameters of the prime mover 12, the alternator 10 is desira'bly the sole source of electrical current for the oberall control circuit. The desirability of having such a single current source is apparent where the prime mover 12 would be used for propulsion purposes so that the electrical power therefor must be self generated. As will be later apparent, the fragmentary por-tion of such an overall circuit by which the present invention is illustrated provides an electrical signal for controlling the rate of operation of the prime mover.

It is desirable to provide a power supply from which positive and negative direct current voltages may be deof the A-C voltage regulator is controlled by a feedback from one or both of the positive and negative output leads 18 and 20, illus-tratively shown by lead 23. The output on leads 18 and 20 provides coarsely regulated positive and negative direct current potentials. Preferably these potentials are then further regulated and ltered to provide substantially constan-t, positive and negative, direct current potentials of equal magnitude. To this end the positive lead 18 and the ground connection 22 extend to a positive voltage regulator 24 and the negative lead 20 and ground connection 22 extend to a negative voltage regulator 28. Employing known circuitry, the outputs of the voltage regulators 24 and 28 provide on the lead 26 and lead 30 respectively substantially constant voltages of equal magnitude and opposite polarity.

The output of the alternator is also employed to derive direct current signals which respectively indicate the actual rate of operation of the prime mover and a desired rate therefor which in the usual case would be under manual control.

In connection with deriving the direct current signal indicative of a desired rate of operation a lead 32 provides an input to a square wave generator 34 from the alternator 10. The actual circuitry employed by the square wave generator 34 may take many forms in accordance with known arrangements of the present state of the art. Energization of the generator 34, however, is preferably derived from the output leads 18 and 20 of the rectifier filter circuit 16. In this fashion the output signal strength of the generator 34, as it is developed across an input resistor 36, will be `greater than the potentials at the outputs of the positive and negative voltage regulators 24 and 28 respectively. It is preferable that the square wave output of the generator 34 have the further characteristic of its positive half cycle being equal toits negative half cycle under any steady state operating condition. The output of the square wave generator 34 is applied to the bases of transistors 38 and 40, the transistor 38 being an NPN type anr the transistor 40 being a PNP type. The collector of transistor 38 is connected to the lead 26 to provide a constant positive potential thereon, while the collector of the transistor 40 is connected to the lead 30 to provide a constant voltage potential thereon which is of the same magnitude as the potential at the collector of transistor 38 but of opposite polarity. The emitters of both the trahsistors 38 and I40 are connected to the primary 42 of a transformer 44 through a relatively large capacitor 46.

When the square wave output from the generator 34 functions as an actuating signal and when it goes positive, the transistor 38 is immediately conductive and results in a current flow through the primary 42. This is to say that the positive voltage (from lead 26) is immediately impressed across -the primary 42. When the square Wave signal goes negative, the transistor 38 immediately becomes non-conductive (as the transistor 40 previously was) and the transistor 40 becomes conductive so that the negative voltage is immediately impressed across the primary 42 and current flow therethrough is in the opposite direction.

The impedance of capacitor 46 over the frequency range of operation should 'be very small compared with that across the primary winding 42 so that the voltage changes obtained by the described switching action of transistors 38 and 40 are impressed, with essentially no change, across the winding 42. This arrangement is particularly effective in inducing equal and opposite current flows in the primary winding 42 without being affected by any asymmetrical relationship of the hysteresis loop of the core of the transformer 44. This is to say that without the capacitor 46 very minute variations in the positive and negative lpotentials from leads 26 and 30 or differences in the characteristics of the transistors 38 and 40, or diierences in the individual characteristics of a particular transformer could result in substantial errors in the output signals induced into the several secondaries of the transformer 44. The capacitor 46 also protects the transistors 38 and 40 from excessive current flow as well as enabling continued operation of the overall circuit at a reduced voltage level in the event there is a failure in the means for applying the positive or negative voltages across winding 42.

Following through on the description of the generation of a direct current signal indicative of a desired speed, reference is made to the secondary 48 of the transformer 44 in which is induced the square wave signal having a constant amplitude with negative and positive pulses being of the same magnitude and of equal time duration under steady state operation. This square wave is then impressed across a primary winding 54 of a transducer 56 through leads 50 and S2 to provide excitation for the transducer 56.

Transducers of the present type are well known to those skilled in the art and are often referred to as linearly variable differential transformers. The transducer 56 further comprises opposed secondary windings 58 and 60. A movable core 62 is displaceable to vary the coupling between the primary and secondary windings. In such transducers there is a null point where the signals induced in the windings 58 and 60 are equal and opposed, and no output from the transducers is provided. Displacement of the core 62 in one direction or the other will respectively provide a signal output from the transducer, of one phase or another, on leads 60 and 64. Such output signal is indicative of the magnitude and direction of displacement of the core 62.

The core 62 is responsive to movement of some controlling parameter or parameter to be controlled and in the present instance is mechanically connected to a throttle lever 68 which the operator can manually set to establish a desired rate of operation for the prime mover 12.

A demodulator 70 is connected to the transducer output leads 64 and 66 and provides the direct current signal which is to be indicative of a desired speed. The demodulator 70 also involves use of circuit means well known to those skilled in the art. Energization of the demodulator 70 involves the use of opposed phase inputs which are preferably synchronized to the excitation of tranducer 56 and to this end further secondary windings 7-2 and 74 are provided on the transformer 44 and operatively connected to th demodulator 70. The output leads 64, 66 are connected to the demodulator 70, and with this arrangement an output is provided on lead 76 which has a magnitude and polarity indicative of a desired rate of operation for the prime mover 12.

In order to provide a direct current signal indicative of the actual speed of the prime mover 12, a further secondary winding 78 is provided on the transformer 44. It will be apparent that the frequency of the square wave signal generated in the winding 78 is directly proportional to the rate of operation of the prime mover 12. This square wave input is then fed by leads 79 and 81 to a direct current converter which employs known means to derive from the square wave input thereto a direct current signal on lead 82 which is indicative of the actual rate of operation of the prime mover 12. The direct current signals on leads 76 and 82 are summed at a summation point 84 from which may be derived an error signal on lead 86. This error signal may then be employed in a known fashion to control the rate of operation of the prime mover 12 so as to reduce the error signal to zero and establish a steady state condition of operation.

It is, of course, known to those skilled in the art that the relative values of the real speed and actual speed signals must be correctly established to provide the abovedescribed nulling type of operation.

It will also be apparent to those skilled in the art that the advantages of the present invention are not necessarily limited to the derivation of a speed error signal as above described, but are equally beneficial in the excitation of transducers employed for other purposes in control circuits for prime movers or the like, and further that certain features relative to the generation of a square wave signal will have broader application than herein described.

Having thus described the invention, what is claimed as novel and desired to be secured by Letters Patent of the United States is:

1. A circuit for excitation of an A-C transducer from a voltage source variable as to frequency and potential, said transducer comprising input and output windings and means for varying the coupling therebetween as a function of physical displacement of a control member whereby the strength of a signal on the output winding is likewise a function of such displacement, said circuit comprising;

means connected to said voltage source for generating a square wave having a fixed voltage amplitude and a frequency directly proportionate to the frequency of the voltage source, said square wave generating means comprising,

a power supply excited from said voltage source and providing positive and negative outputs of substantially constant value,

means connected to sad Voltage source for generating an actuating voltage signal,

` a transformer having primary and secondary windings,

electronic switching means connected to said positive and negative voltage outputs and responsive to said actuating voltage means to alternately impress said positive and negative voltages across the primary of said transformer,

thereby inducing in the transformer secondary winding a square wave output of xed voltage amplitude to be impressed on the input winding of said transducer; and

means impressing said square wave on the input winding of said transducer for the excitation thereof;

whereby amplitude of the voltage on the output winding of said transducer is a function of the coupling with the input winding and independent of variations infrequency and potential of the voltage source.

2. Electrical circuit means as in claim 1 wherein the positive and negative outputs of the power supply are of the same magnitude and less than that of the actuating voltage,

the electronic switching means comprise an NPN transistor and a PNP transistor having their emitters connected together and their collectors respective-ly connected to the positive and negative outputs of said power supply and their bases connected to said actuating voltage generating means, and

vthe primary transformer Winding is connected to said emitters through a relatively large capacitor.

References Cited UNITED STATES PATENTS 2,790,092 4/ 1957 Guth 290-40.2 2,955,210 1071960 Dean et al. 290- 3,046,535 7/1962 Philbin et al. 340-199 3,079,545 2/ 1963 Kretsch et al. 340-199 3,183,422 5/1965 Stamm 290-40 XR 3,204,229 8/ 1965 Dulberger 340-196 3,235,790 2/1966 Collins 340-199 3,354,399 1l/l967 Houpt et al. 340-199 XR ORIS L. RADER, Primary Examiner G. R. SIMMONS, Assistant Examiner U.S. C1. X.R. 290-40; 323-58 

